NO864866L - CONTAINER CLOSING DEVICE. - Google Patents

Description

The present invention relates to container lids and relates more particularly to lids that can prevent sinking (panelling) in containers that are sealed by such lids.

It is well known that the straight or flat side walls of a plastic liquid container can be twisted inwards, which gives the container an undesirable appearance and can create doubts about the quality of the contents.

To understand the reasons for this sinking, one can, for example, think of a liquid container that is partially filled with the product itself, e.g. a liquid, and partly with air, i.e. the volume that is not filled by the liquid product. If the container's recoverable air volume is reduced due to the sealing, the negative pressure will consequently increase. The increased negative pressure in the container can cause the side walls to collapse, i.e. the negative pressure cannot be released without the container volume decreasing. Consequently, subsidence occurs, and the container volume decreases and the pressure changes accordingly.

Sinking is not a problem when the container is made of a material that can withstand the aforementioned volume reduction and the accompanying negative pressure. Glass and metal containers are therefore not subject to subsidence and do not represent the above-mentioned quality problems for the consumer.

However, plastic containers, which are widespread, are constantly subject to subsidence and often show that this is the case.

Motor oil, which must be drained into containers at temperatures significantly higher than room temperature, which can be taken as an example. When the temperature in the oil decreases to room temperature after a suitable cap has been attached, subsidence occurs as a result of the small air space above the oil decreasing in volume and leading to an increasing negative pressure in the container. Consequently, costly and time-consuming measures must be implemented to prevent subsidence. Thus, the motor oil must be subjected to forced cooling prior to packing in the containers. Such measures involve disadvantages, both with regard to costs, but also because the sealing of the finished oil must be postponed, and that shipping can be delayed. Furthermore, the stacking height must be limited because the bottles provide uneven support as a result of the subsidence.

It is an essential purpose of the invention to produce a lid which is designed to prevent such sinking.

It is also an object of the invention to produce closed containers which are designed to prevent such sinking.

It is a further object of the present invention to produce improved and simplified lids or lid parts which facilitate the internal air flow or ventilation so that sinking is prevented.

In order to meet these and other purposes, according to the invention, a container lid part is produced which is arranged to receive a lining for sealing a container, the lid part comprising a top plate and a skirt projecting downwards from the top plate. A first projecting portion downwards from the top plate inside the lid to, with the liner engaged in the lpkk part, define a first air flow channel which runs from the underside of the top plate to the skirt. A second projecting portion projects inwardly from the interior of the skirt of the lid to, with the liner received in the lid portion, define a second air flow channel which runs downwardly along the skirt to the outside of the container, so that the second air flow channel is in flow communication with the first air flow channel. nal.

In a particularly preferred embodiment according to the invention, the first projecting part comprises a number of individual projections, each of which has a first end close to the skirt and a second end located at a distance from the center of the top plate. The second projecting part comprises a number of individual projecting parts in the same number as the first projections and their first ends which are placed next to the first ends of the first projections. The skirt includes internal threads at a distance from the top plate and the protruding parts have other ends next to the threads in the skirt.

According to the invention, a container lid is also produced whose lid part comprises a top plate and a skirt projecting downwards from this, a liner for sealing a container being arranged to be held in place in the lid part and facing the top plate. The liner further has a peripherally raised portion to produce such a seal of a container and a central raised portion within the peripherally raised portion to produce air flow through the liner. The lid portion has a first projecting portion projecting downwardly from the interior of the lid top plate to, together with the liner, define a first air flow channel from the underside of the top plate along the liner to the skirt, and a second raised portion projecting inwardly from the interior of the lid portion skirt to, together with the liner to define a second air flow channel which runs downwardly along the skirt and outside the liner, the second air flow channel being in flow communication with the first air flow channel.

In order to prevent sinking, according to a special embodiment of the invention, a lid is produced where the top plate and the lining together define a valve device to produce an air flow through the lining. The vent device comprises an opening which runs through the liner and a body which projects downwards from the top plate and which is arranged to be placed in a sealing manner in the opening of the liner. The liner includes a hinge portion immediately within its parallel raised portion and a flexible diaphragm within the hinge portion, the hinge sections and the flexible diaphragm supporting the liner's central projecting portion for displacement substantially parallel to the top plate.

The opening in the liner preferably comprises a channel with a first diameter near the top plate and an inwardly tapering channel which runs downwards from the opening to a channel with a second diameter smaller than the first. The top plate body has a frustoconical shape, the largest diameter of which exceeds the first diameter of the opening, while the smallest diameter is smaller than the first diameter.

According to the invention, the lid part for ventilating the container is also used for purposes other than preventing subsidence, as will be apparent from the following.

The preceding and other features and advantages according to the invention will be better understood on the basis of the following detailed description of preferred embodiments with reference to the accompanying drawings, in which: Fig. 1 shows a front view of a lid part according to the invention. Fig. 2 shows a cross-section of the lid part shown in fig. 1 along the plane II-II. Fig. 3 shows a cross-section of one half of the lid part shown in fig. 1, shown along the plane III-III in fig. 2. Fig. 4 shows a top view of a liner for insertion into the lid part shown in fig. 1. Fig. 5 shows a section through the central part of the lining shown along the plane V-V according to fig. 4. Fig. 6 shows an enlarged section of the peripheral part of the liner shown in fig. 4, showing a sealing cone in detail. Fig. 7 shows a cross-section through the central part of the lid part shown in fig. 1-3 and the liner shown according to fig. 4-6, in that the liner is inserted in the lid part, but is not placed on a container. , Fig. 8 shows a cross-section through the central part of the lid part as shown in fig. 1-3 and the liner as shown in fig. 4-6, the liner and lid part being assembled and placed on a container. It is also shown how the shut-off valve can lead ambient air to the container, so that sinking is prevented.

With reference to fig. 1, 2 and 3, the lid part or capsule 10 of the container lid according to the invention is formed in one piece of rigid plastic or other material by casting, so that a unitary body is produced. The top plate 12 has a circular periphery from which a skirt projects downwards. The lid comprises external grip grooves 16 and has an internal annular edge at 18 and is threaded at 20. The underside 22 of the top plate 12 comprises a truncated cone-shaped body 24 which projects downwards centrally from the same in cases where the lid part 10 needs to achieve ventilation in cooperation with a lining, i.e. for the purpose of preventing subsidence, as will be discussed below.

Protruding parts or ribs 26a in the top plate, preferably in a number of three, are mutually separated by equal angular distance in the example shown. They project downwards from the underside 22 of the top plate inside the lid and extend from a first end near the skirt 14, radially inward towards the other ends which are located at a distance from the center of the top plate 12 and from the body 24. Ribs 26b project from the above-mentioned first ends near the top plate 12 axially downward on the inner side of the skirt 14 to a second end location close to the annular edge 18 and the threads 20. In this example, the ribs 26b are continuously and integrally formed in one piece with the ribs 26a and mutually flush with them, but can be arranged differently, as will be apparent from the following.

With reference to fig. 4, 5 and 6 as well as the method to prevent sinking, the liner 28 has a peripheral portion 30 with a flat upper surface 32, and is made of plastic and of a material that is more elastic than the material from which the lid part 10 is made. Sealing bodies 34 and 36 (Fig. 6) in the form of radially inwardly converging cones can project downwards from the underside 38 and are arranged to form a continuous sealing system against the container neck during the movement of the liner and lid part to thereby produce selective air flow into the container so that sinking is prevented .

A frustoconical flexible liner diaphragm 40 is supported by the liner's peripheral portion 30 via a hinge section 41, and projects radially inwards and is preferably integrally formed with this, e.g. in that the part 30 and the section 41 are cast in one piece.

The liner's diaphragm part 40 supports the liner's centrally raised part 42 which has a continuous opening 44. The liner's opening 44 comprises a bore where the part of the bore facing the top plate has a first diameter, while a passage narrows downwards from the opening to a passage with a second diameter which is smaller than the first diameter.

The body 24 of the top plate (Fig. 3, 7 and 8) is preferably truncated, with the largest diameter, i.e. the diameter at the underside 22 of the top plate, being larger than the liner's first opening (bore) diameter, while the smallest diameter of the body, i.e. the diameter at the side facing away from the underside 22 is smaller than the first opening diameter. Furthermore, the top plate body 24 projects further downwards from the underside of the plate 22 than the ribs 26a. These parameter selections ensure a uniform operation of the valve which is formed by the lid part and the lining. Furthermore, the central part of the liner has a significantly greater thickness than the diaphragm part of the liner and its hinge section, like the peripheral liner parts, so that the valve effect is further enhanced by the largely parallel movement of the central part of the liner in the direction away from the top plate, as shall be described in connection with fig. 8 below.

During the assembly of the lid part and the liner 28, the liner is placed in the lower open end of the lid and pressed into the position in which the liner is held in place, see fig. 7. Here the lower edge 4 8 of the liner 28 is in axial engagement with the annular edge 18 which ensures the aforementioned retention. During the placement in such a position, the side wall 50 abuts against the threads 20, the annular edge 18 being elastically bent radially inwards and sliding over the threads and the edge and bent back to its normal shape, as shown in fig. 7.

The liner 28 according to fig. 8 is shown in sealing contact with the upper surface 52a of the container neck 52. It can also be seen that the peripheral part 30 of the liner has its upper surface 32 in compressive contact with the lid part's ribs 26a and its side surface 50 in contact with the lid part's ribs 26b. The lining material is more compressible than the lid part's material and the ribs can consequently penetrate into and form radial and axial depressions in the surfaces 32 and 50, respectively, depending on the torque exerted on the container lid. A number of closed flow paths are thus formed, as a result of a lack of sealing in such recesses, of which the first

(1) extends radially over and/or through such recesses formed by the ribs 26a in the surfaces 32, while the others (2) extend axially downwards, along the skirt 14 through the spaces formed by the ribs 26b in the surface 50. A third flow path ( 3) runner

axially past the edge 18 and through the lid and the container threads, which therefore do not form an airtight engagement with each other.

In the embodiment shown in fig. 8, the resulting negative pressure in the sealed container will contribute to the diaphragm 40 being pulled downwards and the walls of the hinge section 41 being rotated radially outwards in accordance with the downward movement of the diaphragm, so that the central projecting part 42 of the liner is moved largely parallel to the underside 22 of the top plate. This places the flow channel 44 in the liner's centrally projecting part 42 in flow connection with the above-mentioned flow paths (1)-(3). It will be seen that there is a clearance between the plug valve body 24 and the opening 44 of the liner. In this case, the air surrounding the lid part 10, i.e. the atmospheric air, has access to the container through the flow channel 44, so that the contained (trapped) volume of air increases and consequently the oppression subsides. As the negative pressure inside the container decreases when there is a level where the deflection of the draft diaphragm part 40 is suspended, and rather positively forces the diaphragm into the position in which a seal is produced between the plug body 24 and the channel 44 in the lining.

As an example according to the invention, with regard to the prevention of sinking, motor oil or other liquid is filled at higher temperatures, i.e. 180° directly into a container as it is available during manufacture. The container with some air above the oil level is then sealed with a lid according to the invention, as described above, and the container is placed at ambient temperature ready for shipping. The container is therefore not subjected to rapid cooling during filling or closing. It has been shown that lateral subsidence, which otherwise occurs in other cases than with the present invention, does not occur as a result of the pressure-induced movement of the valve of the lid according to the invention, and this occurs selectively during the temperature drop in the liquid.

As stated above, the lid part according to the invention can be used for purposes other than just preventing subsidence. Thus, mention must be made of applications where ventilated liners are used to release positive overpressure from containers. Among such known materials can be mentioned TYVEC and GORTEK manufactured by duPont and W.L. respectively. Gore. Both of these materials are adapted to ventilate internal excess pressure from containers. Such materials can be directly used in the lid part, as they have the above-mentioned flow capacity.

Various changes and variations of the described lid designs and the lid part can be carried out without deviating from the scope of the invention. E.g. the valve formed by the lid part and liner can be designed with an opposite construction to that already shown, e.g. the top plate 24 can be designed as a valve seat designed to selectively close such a liner opening, instead as a plug body which is placed in the liner's central openings. Likewise, the conditional container seal with lining can be designed in a different way than that discussed above, e.g. with one flexible cone instead of two or other sealing surfaces in contact with the container neck. As intended, the ribs 26a may be designed integrally with and flush with the ribs 26b. Their function, which aims to produce flow paths to the liner's opening and to the surroundings, can consequently be realized in other ways than by the flow paths (1) and (2) which are delimited by the liner and lid structures as mentioned above. While engaging threads that do not form airtight contact surfaces produce flow paths (3) as mentioned above, non-threaded engagements will function similarly. Accordingly, the specifically stated embodiments are purely illustrative and in no way limiting. The scope of the invention appears from the following claims.

Claims (10)

1. Container lid part which is arranged to receive a liner for sealing a container, characterized in that the lid part comprises a top plate and a skirt projecting downwards from the top plate, that a first projecting portion projects downwards from the top plate in the interior of the lid to define, together with the liner received in the lid portion, a first airflow channel running from the underside of the top plate to the skirt, and that a second projecting portion projects inwardly from the interior of the skirt into the lid to, with the liner received in the lid portion, define a second airflow channel running downwards along the skirt, the second air flow channel being in flow connection with the first air flow channel. 2. Container lid part in accordance with claim 1, characterized in that the first projecting part comprises a number of individual projections each of which has first ends close to the skirt, and other ends located at a distance from the center of the top plate. * 3. Container lid part in accordance with claim 2, characterized in that the second projecting part comprises a number of individual projections in the same number as the first projections and has first ends flush with the first ends of the first projections. 4. Container lid part in accordance with claim 3, charac- in serted in that the skirt has internal threads at a distance from the top plate, the other projecting parts having other ends next to the threads in the lid skirt. 5. Container lid part in accordance with claim 3, characterized in that the corresponding projections in the first and second projecting parts are mutually flush. 6. Container lid comprising the lid part according to claim 1, and a liner for sealing a container, the liner being firmly placed in the lid part facing the top plate, characterized in that the liner has a peripherally protruding part adapted to produce such a container seal and a central projecting part within the peripherally projecting portion for producing an air flow through the liner. 7. Container lid in accordance with claim 6, characterized in that the top plate and the liner together define a valve device to selectively produce an air flow through the liner. 8. Container lid in accordance with claim 7, characterized in that the valve device comprises an opening that runs through the liner's central projecting part and a body projects downwards from the top plate and is designed for sealing against the liner's opening. 9. Container lid in accordance with claim 8, characterized in that the liner comprises a hinge part within the peripheral protruding part of the liner and a flexible diaphragm immediately inside the hinge part, the flexible diaphragm supporting the central protruding part of the liner for displacement largely parallel to the top plate. 10. Container lid in accordance with claim 9, characterized in that the opening of the liner includes a bore with a first diameter at the part facing the top plate, as a passage narrows downwards from the bore to a passage with a second diameter that is smaller than the first diameter , and the top plate body is frustoconical and has a largest diameter that is larger than the first diameter and a smaller diameter that is smaller than the first diameter.